#185 Nevada-Reno (5-5)

avg: 753.13  •  sd: 87.66  •  top 16/20: 0%

Click on a column to sort  • 
# Opponent Result Game Rating Status Date Event
192 Loyola Marymount Loss 8-9 574.68 Feb 4th Stanford Open
241 Humboldt State Win 12-6 1020.86 Feb 4th Stanford Open
246 California-B Win 9-7 696.21 Feb 4th Stanford Open
192 Loyola Marymount Loss 5-13 99.68 Feb 5th Stanford Open
172 Puget Sound Win 10-9 961.24 Feb 5th Stanford Open
113 Cal Poly-SLO-B Loss 7-11 634.77 Feb 5th Stanford Open
105 California-Davis Loss 7-10 749.57 Feb 5th Stanford Open
293 Idaho Win 15-7 625.52 Mar 4th Big Sky Brawl1
63 Utah Loss 8-10 1082.49 Mar 4th Big Sky Brawl1
- Montana State Win 10-8 982.48 Mar 4th Big Sky Brawl1
**Blowout Eligible

FAQ

What is the uncertainty of the mean?
The uncertainty of the mean is equal to the standard deviation of the set of game ratings, divided by the square root of the number of games. We treated a team’s ranking as a normally distributed random variable, with the USAU ranking as the mean and the uncertainty of the ranking as the standard deviation
What's the algorithm again?
  1. Calculate uncertainy for USAU ranking averge
  2. Model ranking as a normal distribution around USAU averge with standard deviation equal to uncertainty
  3. Simulate seasons by drawing a rank for each team from their distribution. Note the teams in the top 16 (club) or top 20 (college)
  4. Sum the fractions for each region for how often each of it's teams appeared in the top 16 (club) or top 20 (college)
  5. Subtract one from each fraction for "autobids"
  6. Award remainings bids to the regions with the highest remaining fraction, subtracting one from the fraction each time a bid is awarded
Is there a longer explanation of all this?
There is an article on Ulitworld written by Scott Dunham and I that gives a little more context (though it probably was the thing that linked you here)